Beijing National Laboratory for Molecular Sciences, Institute of Chemistry, Chinese Academy of Sciences, Beijing 100190, China.
J Chem Phys. 2013 Mar 21;138(11):114309. doi: 10.1063/1.4795495.
In the previous work of Mikosch et al. [Science 319, 183 (2008)], ion imaging experiments were used to study the Cl(-) + CH3I → ClCH3 + I(-) reaction at collision energies E(rel) of 0.39, 0.76, 1.07, and 1.9 eV. For the work reported here MP2(fc)/ECP/d direct dynamics simulations were performed to obtain an atomistic understanding of the experiments. There is good agreement with the experimental product energy and scattering angle distributions for the highest three E(rel), and at these energies 80% or more of the reaction is direct, primarily occurring by a rebound mechanism with backward scattering. At 0.76 eV there is a small indirect component, with isotropic scattering, involving formation of the pre- and post-reaction complexes. All of the reaction is direct at 1.07 eV. Increasing E(rel) to 1.9 eV opens up a new indirect pathway, the roundabout mechanism. The product energy is primarily partitioned into relative translation for the direct reactions, but to CH3Cl internal energy for the indirect reactions. The roundabout mechanism transfers substantial energy to CH3Cl rotation. At E(rel) = 0.39 eV both the experimental product energy partitioning and scattering are statistical, suggesting the reaction is primarily indirect with formation of the pre- and post-reaction complexes. However, neither MP2 nor BhandH/ECP/d simulations agree with experiment and, instead, give reaction dominated by direct processes as found for the higher collision energies. Decreasing the simulation E(rel) to 0.20 eV results in product energy partitioning and scattering which agree with the 0.39 eV experiment. The sharp transition from a dominant direct to indirect reaction as E(rel) is lowered from 0.39 to 0.20 eV is striking. The lack of agreement between the simulations and experiment for E(rel) = 0.39 eV may result from a distribution of collision energies in the experiment and/or a shortcoming in both the MP2 and BhandH simulations. Increasing the reactant rotational temperature from 75 to 300 K for the 1.9 eV collisions, results in more rotational energy in the CH3Cl product and a larger fraction of roundabout trajectories. Even though a ClCH3-I(-) post-reaction complex is not formed and the mechanistic dynamics are not statistical, the roundabout mechanism gives product energy partitioning in approximate agreement with phase space theory.
在 Mikosch 等人的先前工作中,[Science 319, 183 (2008)],使用离子成像实验研究了 Cl(-) + CH3I → ClCH3 + I(-)反应在碰撞能 E(rel) 为 0.39、0.76、1.07 和 1.9 eV 的情况下的反应。对于这里报道的工作,进行了 MP2(fc)/ECP/d 直接动力学模拟,以获得对实验的原子理解。对于最高三个 E(rel),实验产物能量和散射角分布与实验结果吻合良好,在这些能量下,80%或更多的反应是直接的,主要通过向后散射的反弹机制发生。在 0.76 eV 处有一个小的间接成分,具有各向同性散射,涉及前反应和后反应复合物的形成。在 1.07 eV 处,所有反应都是直接的。将 E(rel) 增加到 1.9 eV 会开辟一条新的间接途径,即绕道机制。产物能量主要分配给直接反应的相对平移,但间接反应的产物能量主要分配给 CH3Cl 的内部能量。绕道机制将大量能量转移到 CH3Cl 的旋转中。在 E(rel) = 0.39 eV 时,实验产物能量分配和散射都是统计的,这表明反应主要是间接的,伴随着前反应和后反应复合物的形成。然而,MP2 和 BhandH/ECP/d 模拟都与实验不符,而是表明反应主要由直接过程主导,如在较高的碰撞能下所发现的那样。将模拟 E(rel) 降低到 0.20 eV 会导致产物能量分配和散射与 0.39 eV 实验一致。随着 E(rel) 从 0.39 降低到 0.20 eV,从主要的直接反应到间接反应的急剧转变引人注目。对于 E(rel) = 0.39 eV,模拟与实验之间的不一致可能是由于实验中碰撞能的分布和/或 MP2 和 BhandH 模拟的不足造成的。对于 1.9 eV 的碰撞,将反应物的旋转温度从 75 K 增加到 300 K,会导致 CH3Cl 产物中更多的旋转能量和更大比例的绕道轨迹。即使没有形成 ClCH3-I(-) 后反应复合物,并且机械动力学不是统计的,绕道机制也会导致产物能量分配与相空间理论大致一致。
